Providing a test head capable of suppressing a probe card from bending.
The test head 40 comprises: a test head main body 51 having a frame 51; an interface apparatus 60 electrically connecting a probe card 20 and the test head main body 50 with each other; and a brake unit 80 positioned between the probe card 20 and the frame 51 to transmit a pressing force F applied to the probe card 20 to the frame 51.
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6. A test head comprising:
a test head main body having a frame; and
an interface apparatus electrically connecting a probe card and the test head main body with each other and a stiffener that reinforces the probe card, wherein
the test head further comprises:
a holding mechanism provided at a top plate of the interface apparatus and configured to hold the probe card;
a limiter provided at the top plate and configured to limit a movement of the holding mechanism in a direction departing from the probe card reinforced by the stiffener; and
a transmitter configured to transmit a pressing force applied to the probe card to the frame, the transmitter having:
a contact member being movable relative to either one of the top plate or the frame and contacting other of the top plate or the frame; and
a lock mechanism provided at either one of the top plate or the frame and configured to lock a relative movement of the contact member.
12. A test head comprising:
a test head main body having a frame; and
an interface apparatus electrically connecting a probe card and the test head main body with each other and a stiffener that reinforces the probe card, wherein
the test head further comprises:
a holding mechanism provided at a top plate of the interface apparatus and configured to hold the probe card;
a limiter provided at the top plate and configured to limit a movement of the holding mechanism in a direction departing from the probe card reinforced by the stiffener; and
a transmitter configured to transmit a pressing force applied to the probe card to the frame, the transmitter having:
a contact member being movable relative to either one of the holding mechanism or the frame and contacting other of the holding mechanism or the frame; and
a lock mechanism provided at either one of the holding mechanism or the frame and configured to lock a relative movement of the contact member.
1. A test head comprising:
a test head main body having a frame; and
an interface apparatus electrically connecting a probe card and the test head main body with each other and a stiffener that reinforces the probe card, wherein
the test head further comprises:
a transmitter positioned between the probe card and the frame and configured to transmit a pressing force applied to the probe card to the frame;
a holding mechanism provided at a top plate of the interface apparatus and configured to hold the probe card; and
a limiter provided at the top plate and configured to limit a movement of the holding mechanism in a direction departing from the probe card reinforced by the stiffener, wherein
the transmitter has:
a contact member being movable relative to either one of the limiter or the frame and contacting other of the limiter or the frame; and
a lock mechanism provided at either one of the limiter or the frame and configured to lock a relative movement of the contact member.
2. The test head as set forth in
the holding mechanism grasps a clamp head provided at a center portion of the probe card.
3. The test head as set forth in
the top plate has a coupling portion which is to be coupled with a head plate of a prober,
a center of the probe card is nearer to the contact member than the coupling portion with respect to a planar view.
4. The test head as set forth in
the transmitter has a biasing member that biases the contact member.
5. The test head as set forth in
the lock mechanism accepts a relative movement of the contact member before the test head main body is positioned relative to a prober, and the lock mechanism locks the relative movement of the contact member after the test head main body is positioned relative to the prober.
7. The test head as set forth in
the holding mechanism grasps a clamp head provided at a center portion of the probe card.
8. The test head as set forth in
the top plate has a coupling portion which is to be coupled with a head plate of a prober,
a center of the probe card is nearer to the contact member than the coupling portion with respect to a planar view.
9. The test head as set forth in
the transmitter has a biasing member that biases the contact member.
10. The test head as set forth in
the lock mechanism accepts a relative movement of the contact member before the test head main body is positioned relative to a prober, and the lock mechanism locks the relative movement of the contact member after the test head main body is positioned relative to the prober.
11. A semiconductor wafer test apparatus comprising:
the test head as set forth in
a prober pressing a semiconductor wafer to the probe card.
13. The test head as set forth in
the holding mechanism grasps a clamp head provided at a center portion of the probe card.
14. The test head as set forth in
the top plate has a coupling portion which is to be coupled with a head plate of a prober,
a center of the probe card is nearer to the contact member than the coupling portion with respect to a planar view.
15. The test head as set forth in
the transmitter has a biasing member that biases the contact member.
16. The test head as set forth in
the lock mechanism accepts a relative movement of the contact member before the test head main body is positioned relative to a prober, and the lock mechanism locks the relative movement of the contact member after the test head main body is positioned relative to the prober.
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The present invention relates to a test head used for testing semiconductor wafers and to a semiconductor wafer test apparatus comprising the test head.
An electronic component test apparatus is known in which, in order to suppress a probe card from bending due to a pressing force transmitted via a semiconductor wafer, a HIFIX is provided with a contact mechanism for receiving such pressing force in the back surface of the probe card (refer to Patent Document 1, for example).
In the above electronic component test apparatus, the head plate of a prober and the top plate of the HIFIX are coupled with each other, and therefore the pressing force received by the probe card is finally transmitted to the head plate. As a consequence, if large pressing force is applied to the probe card, then the force causes the head plate to bend via the HIFIX thereby resulting in that the probe card is also possibly bent. Particularly in the case where the probe card comes to be large and/or of increased pins, the pressing force applied to a semiconductor wafer increases thereby significantly bend the probe card.
The problem to be solved by the present invention is to provide a test head capable of suppressing a probe card from bending and a semiconductor wafer test apparatus comprising such a test head.
The test head according to the present invention is a test head comprising: a test head main body having a frame; and an interface apparatus electrically connecting a probe card and the test head main body with each other, characterized in that the test head further comprises a transmitting device positioned between the probe card and the frame to transmit a pressing force applied to the probe card to the frame.
In the above invention, the test head may further comprise: a holding mechanism provided at a top plate of the interface apparatus to hold the probe card; and a limiting means provided at the top plate to limit a movement of the holding mechanism in a direction departing from the probe card, and the transmitting means may have: a contact part being movable relative to either one of the limiting means or the frame and contacting other of the limiting means or the frame; and a lock mechanism provided at either one of the limiting means or the frame to lock a relative movement of the contact part.
In the above invention, the test head may further comprise a holding mechanism provided at a top plate of the interface apparatus to hold the probe card, and the transmitting means may have: a contact part being movable relative to either one of the top plate or the frame and contacting other of the top plate or the frame; and a lock mechanism provided at either one of the top plate or the frame to lock a relative movement of the contact part.
In the above invention, the test head may further comprise a holding mechanism provided at a top plate of the interface apparatus to hold the probe card, and the transmitting means may have: a contact part being movable relative to either one of the holding mechanism or the frame and contacting other of the holding mechanism or the frame; and a lock mechanism provided at either one of the holding mechanism or the frame to lock a relative movement of the contact part.
In the above invention, the holding mechanism may grasp a clamp head provided at a center portion of the probe card.
In the above invention, the transmitting means may have: a contact part being movable relative to the frame and contacting the probe card; and a lock mechanism provided at the frame to lock a relative movement of the contact part.
In the above invention, the contact part may be positioned at an inner side than a coupling portion of the top plate to be coupled with a head plate of a prober.
In the above invention, the transmitting means may have a biasing means biasing the contact part.
In the above invention, the lock mechanism may accept a relative movement of the contact part before the test head main body is positioned relative to a prober, and the lock mechanism may lock the relative movement of the contact part after the test head main body is positioned relative to the prober.
The semiconductor wafer test apparatus according to the present invention is characterized by comprising the above test head and a prober pressing a semiconductor wafer to the probe card.
According to the present invention, there is involved a transmitting means provided between the probe card and the frame to transmit a pressing force applied to the probe card to the frame of the test head main body, and therefore the probe card is suppressed from bending.
Below, embodiments of the present invention will be explained based on the drawings.
The semiconductor wafer test apparatus 1 according to the present embodiment, which is an apparatus for testing electrical characteristics of DUTs (Devices Under Test) such as integrated circuit elements created on and/or in a semiconductor wafer W, comprises a tester 10, a probe card 20, a prober 30, and a test head 40, as shown in
In this semiconductor wafer test apparatus 1, as shown in
The probe card 20 comprises, as shown in
The contactors 21 are terminals to contact with electrode pads on DUTs of the semiconductor wafer W, and specific examples thereof include Pogo pins, needles, bumps, and the like. These contactors 21 are mounted on the center area of lower surface of the circuit board 22 so as to face the electrode pads on the semiconductor wafer W.
In contrast, a number of connectors 25 which electrically connect the probe card 20 and a HIFIX 60 with each other are mounted on the upper surface of circuit board 22. Also on the upper surface of circuit board 22, the stiffener 23 is provided to surround these connectors 25, thereby reinforcing the probe card 20.
As shown in
In addition, at the upper portion of outer surface of the clamp head 24, as shown in
The prober 30 has a head plate 31 and a carrier arm 33, as shown in
The head plate 31 is a plate positioned at the upper portion of the prober 30, as shown in the same figure. IN the head plate 31, an opening 31a to which the probe card 20 is attached via a holder 34 is formed. In addition, around the opening 31a of head plate 31, hook-shape coupling portions 31b which are engaged with coupling portions 61b of a top plate 61 of the HIFIX 60 are provided.
The carrier arm 33 moves the semiconductor wafer W in X and Y directions and to rotate it around Z-axis in the status where the adsorbing stage 33a adsorbs and holds the semiconductor wafer W, and therefore is capable of positioning the semiconductor wafer W relative to the probe card 20. At the time of testing the semiconductor wafer W, this carrier arm 33 presses the semiconductor wafer W to the probe card 20 with a pressing force F. This allows top ends of the contactors 21 of probe card 20 to contact with electrode pads of DUTs of the semiconductor wafer W, thereby to enable the semiconductor wafer W to be tested.
The test head 40 has, as shown in
As shown in
The HIFIX 60 is an interface apparatus for electrically connecting the test head main body 50 and probe card 20 with each other. This HIFIX 60 has the top plate 61 abutting the head plate 31 of prober 30, and the lower surface of top plate 61 is provided with the hook-like coupling portions 61b to be engaged with the above-mentioned coupling portions 31b of head plate 31. Contact surfaces of the coupling portions 31b and 61b are inclined and therefore, engaging the coupling portions 31b and 61b with each other allows the HIFIX 60 to be fixed to the prober 30.
The HIFIX 60 has connectors 62 to be coupled with the connectors 25 of probe card 20. These connectors 62 are connected with the pin electronics cards (not shown) in the test head main body 50 via cables 63. As the connectors 25 and 62, ZIF connectors (ZIF: Zero Insertion Force) may be used, for example. Note that, without directly connecting the connectors 25 to the pin electronics cards via the cables 63, additional connectors may be further provided therebetween.
As shown in
The center clamp 70 comprises, as shown in
The sleeve 71 is a bottom-having cylinder which has the sleeve contact surface 71a which contacts with the clamp contact surface 24a of the clamp head 24 at the bottom thereof. In addition, around the sleeve contact surface 71a of the sleeve 71, a circular recess 71b is formed to accommodate the slide body 73, and a rib 71c is provided at further outside of the circular recess 71b so as to project downward below the sleeve contact surface 71a. An accommodating groove 71d opened inwardly, which is capable of accommodating portions of the steel balls 74, is formed at the lower portion of the rib 71c.
As shown in
As shown in
Note that the slide body 73 is coupled to the second air cylinder 75 as shown in
In turn, the description will be directed to the brake units 80.
The brake units 80 intervene between the frame 51 of test head main body 50 and the top plate 61 of the HIFIX 60 as shown in
As shown in
As shown in the same figure, the main body block 81 is fixed to the frame 51 of test head main body 50 and sliding hole 81a is formed in the main body block 81. This sliding hole 81a is a hole in which the shaft 82 is slidable up and down in the figure. The elastic member 83 biasing the shaft 82 toward the limit unit 90 is accommodated in the sliding hole 81a. Although the elastic member 83 is configured of a coil-like spring in the present embodiment, the elastic member 83 is not particularly limited to this, and a plate-like spring or rubber may be alternatively used, for example.
The shaft 82 is a rod-like member partially inserted into the sliding hole 81a of main body block 81, and is movable relative to the frame 51. The shaft 82 contacts the supporting block 92 of the limit unit 90 in the status of being biased by the elastic member 83 in the sliding hole 81a.
As shown in
As shown in
It is to be noted that the lock mechanism 84 of brake unit 80 is not limited to the above structure. For example as shown in
In this case, the two grip arms 84a and 84b are coupled to be pivotally movable by the pivot axis 84d and inserted into the ring-like member 84e. The elastic member 84f biases the ring-like member 84e in the direction where the ring-like member 84e departs from the pivot axis 84d (leftward in the figure), and the air cylinder 84g presses the ring-like member 84e in the opposite direction (rightward in the figure) by being supplied with air.
In such a lock mechanism 84, if the shaft 82 is locked, the elastic member 84f biases the ring-like member 84e to move into the opposite direction from the pivot axis 84d. This allows the two grip arms 84a and 84b to be pressed by the inner face of the ring-like member 84e to come close with each other thereby locking the shaft 82. Thus, the elastic member 84f enables the shaft 82 to be locked without air supply in the locking status, and the locking status is stably maintained.
On the other hand, if the shaft 82 is unlocked by the lock mechanism 84, the air cylinder 84g is supplied with air to move the ring-like member 84e toward the pivot axis 84d. This allows the grip arms 84a and 84b to be free from the press by the inner face of the ring-like member 84e thereby releasing the shaft 82 from being locked.
In the present embodiment, as shown in
Moreover, the brake units 80 are not particularly limited to the above structure as long as including a member (or mechanism) which is movable relative to the frame 51 or the limit unit 90 and a member (or mechanism) which is capable of transmitting the pressing force F received by the limit unit 90 to the frame 51.
For example as shown in
In addition as shown in
Furthermore as shown in
As shown in
As shown in
The supporting block 92, which intervenes between the top plate 61 and the main body block 91 as shown in
In the present embodiment, the lock mechanisms of the limit units 90 lock the shafts 93 in the status where the shafts 93 contact the sleeve 71. This limits the sleeve 71 to move upward in the figure.
Functions of the test head 40 according to the present embodiment will be described hereinafter.
As shown in
While the sleeve 71 having received such pressing force F is liable to move in the direction of departing from the probe card 20, the movement is limited by the limit units 90. That is, the pressing force F is transmitted from the sleeve 71 to the limit units 90. In addition, because these limit units 90 are fixed to the top plate 61, the pressing force F is transmitted also to the top plate 61.
Now considering that the top plate 61 is mechanically coupled to the head plate 31 of prober 30, the pressing force F may be finally transmitted to the head plate 31 to bend it, and as a consequence the probe card 20 also possibly bends. Particularly in the case that the top plate 61 or the head plate 31 is thin, problems of such bending of the probe card 20 may be ready for occurring significantly. Given the foregoing, there may be considered to increase the stiffness of stiffener 23 in order to suppress the probe card 20 from bending, however, increasing the thickness of stiffener 23 is with limitations.
In contrast, the test head 40 according to the present embodiment comprises the brake units 80 for transmitting this pressing force F to the frame 51 of test head main body 50. According to these brake units 80, the lock mechanisms 84 mounted relative to the frame 51 lock the shafts 82 contacting the supporting blocks 92. Consequently, the pressing force F transmitted to the limit units 90 is further transmitted to the frame 51 via the brake units 80 before being transmitted to the head plate 31.
That is, according to the present embodiment, the pressing force F applied to the probe card 20 is transmitted to the frame 51 of test head main body 50 through the pathway including center clamp 70, limit units 90, and brake units 80 in this order.
In the present embodiment, each of four brake units 80 bears 100 kg or more load and therefore, if the pressing force F is 400 kg or less, the pressing force F is allowed to be transmitted without any loss to the frame 51 of test head main body 50.
In addition, the test head main body 50, which has the weight of approximately 1,000 kg, is capable of sufficiently receiving the pressing force F (approximately 400 kg) applied to the probe card 20.
Thus, the pressing force F is transmitted to the rigid frame 51 via the brake units 80, and as a consequence the head plate 31 is prevented from readily bending and the probe card 20 is accordingly also suppressed from bending. The suppressed bending of the probe card 20 prevents electrical contact failures between the contactors 21 of probe card 20 and DUTs of semiconductor wafer W.
Moreover, according to the present embodiment, the brake units 80 and the limit units 90 are arranged with substantially equal intervals in the circumference direction around the center O of the probe card 20, as shown in
Furthermore, according to the present embodiment, the center clamp 70 grasps the clamp head 24 provided at the center portion of the probe card 20 to directly receive the pressing force F to be received by the probe card 20. This allows to respond to the pressing force F regardless of the stiffness of the stiffener 23 thereby being advantageous in cost and handling.
In addition, according to the present embodiment, the shafts 82 of brake units 80 are located at inner side relative to the top coupling portions 61b (nearer the center O), as shown in
Although the brake units 80 according to the present embodiment involve the shafts 82 contacting the limit units 90, the present embodiment is not particularly limited to this. For example as shown in
Note that, although the brake units 80 are attached to the frame 51 and the shafts 82 are caused to contact the limit units 90 in the present embodiment, this relationship may be reversed. For example as shown in
Also note that, as shown in
Still also note that, without providing the limit units 90 as shown in
Further note that, without providing the center clamp 70 and the limit units 90 as shown in
A method of attaching the probe card 20 according to the present embodiment will be described hereinafter.
Initially, the HIFIX 60 having been attached with the center clamp 70 and the limit units 90 is mounted to the test head main body 50 having been attached with the brake units 80. In this status the lock mechanisms 84 of brake units 80 are released from locking, and the relative movement of the shafts 82 is accepted. Likewise, the lock mechanisms of limit units 90 are also released from locking, and the relative movement of the shafts 93 is accepted. Therefore, the mechanical connection between the HIFIX 60 and the test head main body 50 is in a floating status via the springs 64.
Then, as shown in
In this status the relative movement of the shafts 82 is still accepted, and as shown by (i) in
Then, the test head main body 50 is positioned relative to the prober 30. This positioning of the test head main body 50 is performed, although not shown, by fitting guide pins provided on the prober 30 into respective guide holes formed at the lower surface of the test head main body 50.
Thereafter, the shafts 82 of brake units 80 are locked as shown by (ii) in
Note that the locking of the shafts 82 may be performed after the coupling portions 31b of the head plate 31 and the coupling portions 61b of the top plate 61 are coupled with one another (after (vi) shown in
Next, as shown by (iii) in
In turn as shown by (iv) in the same figure, the center clamp 70 holds the clamp head 24 of probe card 20.
More specifically as shown in
Thereafter as shown in
Then, although not particularly shown, the second air cylinder 75 is compressed after the limit units 90 are locked. This allows the slide body 73 to be lifted up relative to the sleeve 71, resulting in that the contact positions between the steel balls 74 and the engaging groove 24c relocates from the approximate middle area of the engaging groove 24c to the upper area of the engaging groove 24c, and as a consequence the sleeve contact surface 71a and the clamp contact surface 24a come to close contact with each other. Note that the control of the first and second air cylinders 72 and 75 and the limit units 90 is performed by the controller 100 shown in
Next, as shown by (v) in
Then, as shown by (vi) in
As described hereinbefore, according to the present embodiment, the lock mechanisms 84 of brake units 80 accept the relative movement of the shafts 82 before the positioning of the test head main body 50, and the lock mechanisms 84 locks the relative movement of the shafts 82 after the positioning of the test head main body 50. For this reason, every time the test head 40 is caused to dock with the prober 30 in association with maintenance, component replacement, and the like, the shafts 82 are to be newly fixed in the condition where the shafts 82 stand to extend between the HIFIX 60 and the test head main body 50, and therefore the pressing force F applied to the probe card 20 is ensured to be transmitted to the frame 51 even if the space between the HIFIX 60 and the test head main body 50 changes.
It is to be noted that the embodiments as explained above are described to facilitate understanding of the present invention and are not described to limit the present invention. Therefore, it is intended that the elements disclosed in the above embodiments include all substitutions, modifications and equivalents to fall within the technical scope of the present invention.
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